Mass spectrometric identification of the trypsin cleavage pathway in lysyl-proline containing oligotuftsin peptides.

Trypsin cleaves specifically peptide bonds at the C-terminal side of lysine and arginine residues, except for -Arg-Pro- and -Lys-Pro- bonds which are normally resistant to proteolysis. Here we report evidence for a -Lys-Pro- tryptic cleavage in modified oligotuftsin derivatives, Ac-[TKPKG]4-NH2) (1), using high-resolution mass spectrometry and HPLC as primary methods for analysis of proteolytic reactions. The proteolytic susceptibility of -Lys-Pro- bonds was strongly dependent on flanking residues, and the flexibility of the peptide backbone might be a prerequisite for this unusual cleavage. While -Lys-Gly- bonds in 1 were rapidly cleaved, the modification of these Lys residues by the attachment of a ss-amyloid(4-10) epitope to yield -Lys(X)-Gly derivatives prevented cleavage of this bond, and provided trypsin cleavage of -Lys-Pro- bonds, the pathway of this degradation being independent on the type of Lys-N(epsilon)-side chains (acetyl group, amino acid, peptide). Substitution of the Lys residues by Ala at the P'2 positions decreased the tryptic cleavage, while replacement of the bulky side chain of Thr at the P2 positions strongly increased the cleavage of -Lys-Pro- bonds. Circular dichroism (CD) data of the modified oligotuftsin derivatives are in accord with enhanced flexibility of the peptide backbone, as a prerequisite for increased susceptibility to cleavage of -Lys-Pro- bonds. These results obtained of oligotuftsin derivatives might have implications for the proteolytic degradation of target peptides that require specific conformational preconditions.     

Acquisition of endonuclease specificity during evolution of L1 retrotransposon

L1 is the most proliferative autonomous retroelement that comprises about 20% of mammalian genomes. Why L1s have proliferated so extensively in mammalian genomes is an important yet unsolved question. L1 copies are amplified via retrotransposition, in which the DNA cleavage specificity by the L1-encoded endonuclease (EN) primarily dictates sites of insertion. Whereas mammalian L1s show target preference for 5'-TTAAAA-3', other L1-like elements exhibit various degrees of target specificity. To gain insights on diversification of the EN specificity during L1 evolution, ENs of zebrafish L1 elements were analyzed here. We revealed that they form 3 discrete clades, M, F, and Tx1, which is in stark contrast to a single L1 clade in mammalian species. Interestingly, zebrafish clade M elements cluster as a sister group of mammalian L1s and show target-site preference for 5'-TTAAAA-3'. In contrast, elements of the clade F, the immediate outgroup of the clade M, show little specificity. We identified certain clade-specific amino acid residues in EN, many of which are located in the cleft that recognizes the substrate, suggesting that these amino acid alterations have generated 2 types of ENs with different substrate specificities. The distribution pattern of the 3 clades suggests a possibility that the acquisition of target specificity by the L1 ENs improved the L1 fitness under the circumstances in mammalian hosts.     

Assembly Pathway and Characterization of the RAG1/2-DNA Paired and Signal-end Complexes

Mammalian immune receptor diversity is established via a unique restricted set of site-specific DNA rearrangements in lymphoid cells, known as V(D)J recombination. The lymphoid-specific RAG1-RAG2 protein complex (RAG1/2) initiates this process by binding to two types of recombination signal sequences (RSS), 12RSS and 23RSS, and cleaving at the boundaries of RSS and V, D, or J gene segments, which are to be assembled into immunoglobulins and T-cell receptors. Here we dissect the ordered assembly of the RAG1/2 heterotetramer with 12RSS and 23RSS DNAs. We find that RAG1/2 binds only a single 12RSS or 23RSS and reserves the second DNA-binding site specifically for the complementary RSS, to form a paired complex that reflects the known 12/23 rule of V(D)J recombination. The assembled RAG1/2 paired complex is active in the presence of Mg²⁺, the physiologically relevant metal ion, in nicking and double-strand cleavage of both RSS DNAs to produce a signal-end complex. We report here the purification and initial crystallization of the RAG1/2 signal-end complex for atomic-resolution structure elucidation. Strict pairing of the 12RSS and 23RSS at the binding step, together with information from the crystal structure of RAG1/2, leads to a molecular explanation of the 12/23 rule.     

Biochemical analysis of pistol self-cleaving ribozymes

Pistol RNAs are members of a distinct class of self-cleaving ribozymes that was recently discovered by using a bioinformatics search strategy. Several hundred pistol ribozymes share a consensus sequence including 10 highly conserved nucleotides and many other modestly conserved nucleotides associated with specific secondary structure features, including three base-paired stems and a pseudoknot. A representative pistol ribozyme from the bacterium Lysinibacillus sphaericus was found to promote RNA strand scission with a rate constant of ∼10 min⁻¹ under physiological Mg²⁺ and pH conditions. The reaction proceeds via the nucleophilic attack of a 2′-oxygen atom on the adjacent phosphorus center, and thus adheres to the same general catalytic mechanism of internal phosphoester transfer as found with all other classes of natural self-cleaving ribozymes discovered to date. Analyses of the kinetic characteristics and the metal ion requirements of the cleavage reaction reveal that members of this ribozyme class likely use several catalytic strategies to promote the rapid cleavage of RNA.     

Development of substrate analogue inhibitors for the human airway trypsin-like protease HAT

A series of substrate analogue inhibitors of the serine protease HAT, containing a 4-amidinobenzylamide moiety as the P1 residue, was prepared. The most potent compounds possess a basic amino acid in the d-configuration as P3 residue. Whereas inhibitor 4 (K_i 13 nM) containing proline as the P2 residue completely lacks selectivity, incorporation of norvaline leads to a potent inhibitor (15, K_i 15 nM) with improved selectivity for HAT in comparison to the coagulation proteases thrombin and factor Xa or the fibrinolytic plasmin. Selected inhibitors were able to suppress influenza virus replication in a HAT-expressing MDCK cell model.     

MMP9 mediates MICA shedding in human osteosarcomas

The MICA (MHC class I chain-related molecule A) is a ligand for the activating immunoreceptor NKG2D (natural killer group 2, member D). NKG2D recognizes MICA expressing at the cell surface for cell elimination. Although MICA is overexpressed in many kinds of tumours, tumour cells can cleverly escape immunosurveillance. One underlying mechanism for immunoescape is tumour-derived MICA shedding. In this study, we report that osteosarcoma-derived MICA results from proteolytic cleavage of MICA α3 ectodomain. sMICA (soluble MICA) might be released in the early stage of disease. A MMP9 (matrix metalloproteinase 9, gelatinase B)-specific inhibitor suppressed sMICA release, indicating that MMP9 is critically involved in the osteosarcoma-associated proteolytic release of sMICA, which facilitates tumour immune escape. Using a specific MMP inhibitor might represent a double-edged sword, where it can inhibit tumour invasion and restore antitumour immune response.     

Studies of morphogenesis at the Department of Embryology, Moscow State University: Towards understanding the dynamic architecture of development

This is a review of studies on morphogenesis carried out at the Department of Embryology, Moscow State University, over the past 30 years. The main direction of studies has been to reveal and describe the properties of self-organizing fields of mechanical stresses in developing embryos.     

Binding of oxindole-Schiff base copper(II) complexes to DNA and its modulation by the ligand

Previous studies on copper(II) complexes with oxindole-Schiff base ligands have shown their potential antitumor activity towards different cells, inducing apoptosis through a preferential attack to DNA and/or mitochondria. Herein, we better characterize the interactions between some of these copper(II) complexes and DNA. Investigations on its binding ability to DNA were carried out by fluorescence measurements in competitive experiments with ethidium bromide, using plasmidial or calf-thymus DNA. These results indicated an efficient binding process similar to that observed with copper(II)-phenanthroline species, [Cu(o-phen)₂]²⁺, with binding constants in the range 3 to 9 × 10² M^− 1. DNA cleavage experiments in the presence and absence of distamycin, a recognized binder of DNA, indicated that this binding probably occurs at major or minor groove, leading to double-strand DNA cleavage, and being modulated by the imine ligand. Corroborating these data, discrete changes in EPR spectra of the studied complexes were observed in the presence of DNA, while more remarkable changes were observed in the presence of nucleotides (AMP, GMP, CMP or UMP). Additional evidence for preferential coordination of the copper centers to the bases guanine or cytosine was obtained from titrations of these complexes with each nucleotide, monitored by absorption spectral changes. Therefore, the obtained data point out to their action as groove binders to DNA bases, rather than as intercalators or covalent cross-linkers. Further investigations by SDS PAGE using ³²P-ATP or ³²P-oligonucleotides attested that no hydrolysis of phosphate linkage in DNA or RNA occurs, in the presence of such complexes, confirming their main oxidative mechanism of action.